TY - GEN
T1 - Algorithms and Barriers in the Symmetric Binary Perceptron Model
AU - Gamarnik, David
AU - Kizildag, Eren C.
AU - Perkins, Will
AU - Xu, Changji
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - The binary (or Ising) perceptron is a toy model of a single-layer neural network and can be viewed as a random constraint satisfaction problem with a high degree of connectivity. The model and its symmetric variant, the symmetric binary perceptron (SBP), have been studied widely in statistical physics, mathematics, and machine learning.The SBP exhibits a dramatic statistical-to-computational gap: the densities at which known efficient algorithms find solutions are far below the threshold for the existence of solutions. Furthermore, the SBP exhibits a striking structural property: at all positive constraint densities almost all of its solutions are 'totally frozen' singletons separated by large Hamming distance [1], [2]. This suggests that finding a solution to the SBP may be computationally intractable. At the same time, however, the SBP does admit polynomial-time search algorithms at low enough densities. A conjectural explanation for this conundrum was put forth in [3]: efficient algorithms succeed in the face of freezing by finding exponentially rare clusters of large size. However, it was discovered recently that such rare large clusters exist at all subcritical densities, even at those well above the limits of known efficient algorithms [4]. Thus the driver of the statistical-to-computational gap exhibited by this model remains a mystery. In this paper, we conduct a different landscape analysis to explain the statistical-to-computational gap exhibited by this problem. We show that at high enough densities the SBP exhibits the multi Overlap Gap Property (m-OGP), an intricate geometrical property known to be a rigorous barrier for large classes of algorithms. Our analysis shows that the m-OGP threshold (a) is well below the satisfiability threshold; and (b) matches the best known algorithmic threshold up to logarithmic factors as m ? 8. We then prove that the m-OGP rules out the class of stable algorithms for the SBP above this threshold. We conjecture that the m ? 8 limit of the m-OGP threshold marks the algorithmic threshold for the problem. Furthermore, we investigate the stability of known efficient algorithms for perceptron models and show that the Kim-Roche algorithm [5], devised for the asymmetric binary perceptron, is stable in the sense we consider.
AB - The binary (or Ising) perceptron is a toy model of a single-layer neural network and can be viewed as a random constraint satisfaction problem with a high degree of connectivity. The model and its symmetric variant, the symmetric binary perceptron (SBP), have been studied widely in statistical physics, mathematics, and machine learning.The SBP exhibits a dramatic statistical-to-computational gap: the densities at which known efficient algorithms find solutions are far below the threshold for the existence of solutions. Furthermore, the SBP exhibits a striking structural property: at all positive constraint densities almost all of its solutions are 'totally frozen' singletons separated by large Hamming distance [1], [2]. This suggests that finding a solution to the SBP may be computationally intractable. At the same time, however, the SBP does admit polynomial-time search algorithms at low enough densities. A conjectural explanation for this conundrum was put forth in [3]: efficient algorithms succeed in the face of freezing by finding exponentially rare clusters of large size. However, it was discovered recently that such rare large clusters exist at all subcritical densities, even at those well above the limits of known efficient algorithms [4]. Thus the driver of the statistical-to-computational gap exhibited by this model remains a mystery. In this paper, we conduct a different landscape analysis to explain the statistical-to-computational gap exhibited by this problem. We show that at high enough densities the SBP exhibits the multi Overlap Gap Property (m-OGP), an intricate geometrical property known to be a rigorous barrier for large classes of algorithms. Our analysis shows that the m-OGP threshold (a) is well below the satisfiability threshold; and (b) matches the best known algorithmic threshold up to logarithmic factors as m ? 8. We then prove that the m-OGP rules out the class of stable algorithms for the SBP above this threshold. We conjecture that the m ? 8 limit of the m-OGP threshold marks the algorithmic threshold for the problem. Furthermore, we investigate the stability of known efficient algorithms for perceptron models and show that the Kim-Roche algorithm [5], devised for the asymmetric binary perceptron, is stable in the sense we consider.
KW - average-case complexity
KW - Binary perceptron
KW - neural networks
KW - overlap gap property
KW - random CSP
KW - statistical-to-computational gap
UR - http://www.scopus.com/inward/record.url?scp=85146321055&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85146321055&partnerID=8YFLogxK
U2 - 10.1109/FOCS54457.2022.00061
DO - 10.1109/FOCS54457.2022.00061
M3 - Conference contribution
AN - SCOPUS:85146321055
T3 - Proceedings - Annual IEEE Symposium on Foundations of Computer Science, FOCS
SP - 576
EP - 587
BT - Proceedings - 2022 IEEE 63rd Annual Symposium on Foundations of Computer Science, FOCS 2022
PB - IEEE Computer Society
T2 - 63rd IEEE Annual Symposium on Foundations of Computer Science, FOCS 2022
Y2 - 31 October 2022 through 3 November 2022
ER -